The conversion of saline-alkali soils into paddy fields for long-term rice cultivation involves multiple disturbances,and as a result,soil microbial communities are altered to adapt to changing environmental condition...The conversion of saline-alkali soils into paddy fields for long-term rice cultivation involves multiple disturbances,and as a result,soil microbial communities are altered to adapt to changing environmental conditions.However,a comprehensive understanding of the succession of soil bacterial communities that occurs during this process is still lacking.In the present study,we utilized data obtained from paddy fields of different rice cultivation years(0-23 years)to investigate the compositional and functional succession of soil bacterial communities.We focused on core bacterial taxa that were specifically enriched at different successional stages.Generalized joint attribute modeling(GJAM)was used to identify core bacterial taxa.Results indicated that the bare saline-alkali soil(0 year,prior to any rice cultivation)shared few core amplicon sequence variants(ASVs)with paddy fields.In the bare saline-alkali soil,Longimicrobiaceae from the phylum Gemmatimonadetes was dominant,while the dominance was subsequently replaced by Burkholderiaceae and Pedosphaeraceae--phyla affiliated with Proteobacteria and Verrucomicrobia--after 5 and 23 years of rice cultivation,respectively.The relative abundances of nitrogen metabolism functions in the core bacterial communities of the bare saline-alkali soil were higher than those at other successional stages,while sulfur metabolism functions exhibited the opposite trend.These indicated that the role of the core bacterial taxa in mediating nutrient cycling also evolved and adapted to changing soil conditions as rice cultivation was established.Redundancy analysis(RDA)indicated that the composition of the core bacterial community in paddy fields with rice cultivation for 0,2 and 4,6,8,10,and 12,and 20 and 23 years were driven by soil nitrate nitrogen content,pH,available phosphorus content,and the ratio of total carbon to total nitrogen,respectively.In summary,the present study provides insights into the succession of soil bacterial communities and core bacterial taxa that occurs during long-term rice cultivation.展开更多
The presence of the blood–brain barrier limits the drug concentration in the brain,while low concentrations of antibiotics make it difficult to kill infecting bacteria and tends to induce drug resistance,making the c...The presence of the blood–brain barrier limits the drug concentration in the brain,while low concentrations of antibiotics make it difficult to kill infecting bacteria and tends to induce drug resistance,making the clinical treatment of bacterial meningitis challenging.Herein,a nose-to-brain delivery strategy of small-sized nanozyme has been fabricated for combating bacterial meningitis,to overcome the low drug concentration and drug resistance.This strategy was achieved by a proteinsupported Au nanozyme(ANZ).With a particle size of less than 10 nm,it possesses both glucose oxidase-like and peroxidase-like activities and can generate large amounts of reactive oxygen species through a cascade effect without the addition of external H_(2)O_(2).Benefiting from the cascade catalytic amplification effect generated by its dual enzymelike activities,ANZ shows significant broad-spectrum antibacterial activity without inducing bacterial resistance in vitro.Notably,small-sized ANZ exhibits higher brain entry efficiency and greater accumulation after intranasal administration compared to oral or intravenous administration.In a mouse model of bacterial meningitis,the mice treated with ANZ had lower bacterial loads in the brain and higher survival and clinical behavior scores compared to the classical antibiotic ceftriaxone.Additionally,the meningitis mice exhibited undamaged cognitive and behavioral abilities,indicating the excellent biocompatibility of ANZ.The above results demonstrate that nose-to-brain delivery of ANZ exhibits high intracerebral accumulation,strong antibacterial efficacy and does not lead to bacterial resistance.It holds broad prospects for the treatment of bacterial meningitis.展开更多
This study evaluated the antibacterial effects of 2%lidocaine and its combination with 0.9%saline solution on Escherichia coli infection in superficial surgical wounds in Wistar rats.The goal was to determine if these...This study evaluated the antibacterial effects of 2%lidocaine and its combination with 0.9%saline solution on Escherichia coli infection in superficial surgical wounds in Wistar rats.The goal was to determine if these treatments could effectively reduce E.coli Colony Forming Units(CFUs)below the critical threshold of 1×105.Seventy male Wistar rats were divided into seven groups,each undergoing different interventions to assess the antibacterial efficacy of lidocaine,with outcomes measured through bacterial cultures and CFU quantification.Results demonstrated a Log10reduction of approximately 0.44 in E.coli CFUs following infiltration with 2%lidocaine.The combined use of 2%lidocaine infiltration and 0.9%saline irrigation resulted in nearly complete suppression of bacterial growth.These findings suggest that these simple interventions could be valuable in emergency surgical settings to mitigate the risk of surgical site infections and serve as effective prophylactic measures.increase in hospital stay,which represents an additional cost in terms of expenses and directly impacts the patient's outcome.11Several lines of evidence point to 104colony forming units per gram of tissue(CFUs/g)as the threshold at which healing generally begins to slow.12Knowledge of the antibacterial activity of lidocaine has been used to prevent bacterial contamination of other lipid-based anesthetics,such as propofol,with a significant decrease in bacterial development13-15and its antifungal effect.15,16Other effects attributed to lidocaine concerning systemic inflammatory response are the inhibition of granulocyte adhesion at sites of inflammation,decreased leukocyte adhesion during endotoxemia,and decreased macromolecular filtration;it is suggested that it may play a therapeutic role in endothelial damage during sepsis.17-19On the other hand,different measures have been taken to reduce the surgical wound infection rate,such as prophylactic antibiotics and local wound care,including pressure irrigation with 0.9% saline solution,with good results.20The antibacterial effect of lidocaine has been demonstrated in an animal model21;however,no model resembles surgical wound infection and the use of lidocaine to prevent infection.This study aimed to demonstrate that using 2% lidocaine(2 mL/g of tissue)will reduce the E.coli CFUs below 1×105in an infected superficial surgical wound in an experimental model.展开更多
Bacterial infection presents formidable challenges that frequently culminate in the malfunction of metal implants.Traditional surface treatment methods struggle to effectively achieve controllable management of bacter...Bacterial infection presents formidable challenges that frequently culminate in the malfunction of metal implants.Traditional surface treatment methods struggle to effectively achieve controllable management of bacterial infections associated with metal implants.To effectively enhance the antibacterial capabilities and preventing bacterial adhesion,electroactive materials have emerged as a groundbreaking strategy for surface modification of metal.By responding to external signals,the electroactive materials can improve antibacterial properties and resistance to bacterial adhesion on the implant surface through harnessing the electrostatic interaction of charges,ion release,oxidation of reactive oxygen species(ROS),electron transfer,and the involvement of cellular immunity.This review delves into the principles of how electroactive materials confer implants with antibacterial properties and antibacterial adhesion,while also summarizing the latest research breakthroughs in their application for surface modification.These strategies successfully strike a balance between the antibacterial and the antimicrobial performance of the implant surface.Lastly,the review examines the limitations and ongoing challenges faced by electroactive material modification technology in implant applications,and sketches out the future trajectory and potential innovative avenues in this promising field.展开更多
Host-derived small RNAs are emerging as critical regulators in the dynamic interactions between host tissues and the microbiome,with implications for microbial pathogenesis and host defense.Among these,transfer RNA-de...Host-derived small RNAs are emerging as critical regulators in the dynamic interactions between host tissues and the microbiome,with implications for microbial pathogenesis and host defense.Among these,transfer RNA-derived small RNAs(tsRNAs)have garnered attention for their roles in modulating microbial behavior.However,the bacterial factors mediating tsRNA interaction and functionality remain poorly understood.In this study,using RNA affinity pull-down assay in combination with mass spectrometry,we identified a putative membrane-bound protein,annotated as P-type ATPase transporter(PtaT)in Fusobacterium nucleatum(Fn),which binds Fn-targeting tsRNAs in a sequence-specific manner.Through targeted mutagenesis and phenotypic characterization,we showed that in both the Fn type strain and a clinical tumor isolate,deletion of ptaT led to reduced tsRNA intake and enhanced resistance to tsRNA-induced growth inhibition.Global RNA sequencing and label-free Raman spectroscopy revealed the phenotypic differences between Fn wild type and PtaT-deficient mutant,highlighting the functional significance of PtaT in purine and pyrimidine metabolism.Furthermore,AlphaFold 3 prediction provides evidence supporting the specific binding between PtaT and Fn-targeting tsRNA.By uncovering the first RNA-binding protein in Fn implicated in growth modulation through interactions with host-derived small RNAs(sRNAs),our study offers new insights into sRNA-mediated host-pathogen interplay within the context of microbiome-host interactions.展开更多
Honey, an apicultural product with a complex chemical composition, contains numerous bioactive compounds with potential antimicrobial effects. This study investigated the effect of Apis mellifera honey from Brazil’s ...Honey, an apicultural product with a complex chemical composition, contains numerous bioactive compounds with potential antimicrobial effects. This study investigated the effect of Apis mellifera honey from Brazil’s Central-West Region, combined with antibiotics, on bacterial membrane permeability, exploring the contributions of bioactive compounds and the botanical origin of honey. Six fresh Apis mellifera honey samples and their fractions (hexane and ethyl acetate) were analyzed, for a total of 18 samples. The bacteria Staphylococcus epidermidis, Helicobacter pylori and Enterococcus faecalis were used for antibacterial activity tests, which included minimum inhibitory concentration (MIC) determination and synergistic effect (checkerboard) assays. The total polyphenol and flavonoid contents were quantified, and the botanical origin was determined based on pollen analysis. The tested honey samples significantly affected bacterial membrane permeability when combined with rifampicin and clarithromycin. Although many honey-derived bioactive compounds, when isolated, did not exhibit significant activity against these bacteria, the additive or synergistic effect of multiple compounds acting on different targets appears to potentiate the antibacterial action. Descriptive statistical analysis, including means and 95% confidence intervals, confirmed the relevance of the findings. This study has provided an important discovery: Honey has an effect on bacterial membrane permeability, although the specific mechanisms involved in this process require further investigation.展开更多
Wild peanut(Arachis)species are promising sources of disease resistance for improving peanut cultivars.The objective of this study was to assess cross-compatibility among cultivated and wild peanuts in crosses between...Wild peanut(Arachis)species are promising sources of disease resistance for improving peanut cultivars.The objective of this study was to assess cross-compatibility among cultivated and wild peanuts in crosses between eight peanut cultivars and 27 wild species carrying the A,B,E,Ex,F,K,P,and H genomes.Embryo culture and chromosome doubling led to polyploids representing hybrids between cultivated peanut and A.stenosperma,A.macedoi,A.duranensis,A.villosa,and A.diogoi.The first two showed greater resistance to bacterial wilt than their cultivated parents.DNA markers were developed for verifying the hybrids and for identifying translocation or introgression lines with alien chromosome fragments.展开更多
Rice-fish coculture(RFC)has aroused extensive concern for its contribution to food security and resource conservation,but whether it can improve soil phosphorus(P)availability and affect microbe-mediated P turnover re...Rice-fish coculture(RFC)has aroused extensive concern for its contribution to food security and resource conservation,but whether it can improve soil phosphorus(P)availability and affect microbe-mediated P turnover remains elusive.Herein,we conducted a microcosm experiment to assess the impacts of RFC combined with(50 mg P kg^(-1)as KH2PO4)and without inorganic P addition on P fractions,P availability,and phoD-harboring bacterial community composition.The results revealed that RFC without P addition significantly improved P availability and phosphatase activity in paddy soil,while soil available P(AP),pH,and microbial biomass P(MBP)contributed to regulating P fractions.Moreover,the phoD-harboring bacterial abundance was linked to phosphatase activity,AP,total carbon(TC),and total P(TP)contents,and the ratios of TC to total nitrogen(TN)and TN to TP.We also found that the keystone taxa of phoD-harboring bacteria contributed to phosphatase production as well as organic P mineralization,thereby improving P availability.Our findings suggest that RFC without P addition is beneficial for promoting the expression of phoD-harboring bacterial functions to improve the capacity of P mineralization.Overall,our study provides insights into the responses of phoD-harboring bacterial functions for P turnover to RFC combined with and without P addition,showing the potential utilization of P resources in agricultural soil and the contribution of phosphatase activity to P acquisition in agriculture ecosystem.展开更多
Solar-driven Fenton-like reactions are promising strategies for degrading pharmaceutical wastewater to address environmental challenges and antibiotic pollution.However,its efficacy is limited by suboptimal light abso...Solar-driven Fenton-like reactions are promising strategies for degrading pharmaceutical wastewater to address environmental challenges and antibiotic pollution.However,its efficacy is limited by suboptimal light absorption efficiency,rapid charge recombination,and inadequate interfacial charge transfer.In this study,an inorganic/organic S-scheme photo-Fenton system of pseudobrookite/carbon nitride(FTOCN)was synthesized via a hydrothermally coupled calcination process for the effective purification of tetracycline antibiotics under visible-light irradiation.The optimized FTOCN-2 heterostructure exhibits a significantly enhanced TC degradation capacity of 90%within 60 min.The rate constant of FTOCN-2 is 1.6 and 5.2 times greater than those of FTO and CN,respectively.Furthermore,FTOCN exhibits high antibacterial efficacy,highlighting its potential application in the purification of natural water.Measurements via a range of analytical techniques,including Kelvin probe force microscopy,density functional theory calculations,in situ X-ray photoelectron spectroscopy,and femtosecond transient absorption spectroscopy,corroborate the S-scheme mechanism.This study provides a novel perspective for the development of photo-Fenton systems with S-scheme heterojunctions for water purification.展开更多
Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is cruci...Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is crucial to advancing rice breeding program and supporting smallholder farmers.Transcription Activator-Like effectors(TALes)are key virulence factors in Xoo,with some targeting the susceptibility(S)genes such as the sugar transporter SWEET genes in rice.Among these,SWEET14 is an important S gene,with its promoter bound by the TALe TalC which exists across all sequenced African Xoo isolates.In the present study,we utilized CRISPR/Cas9-based cytidine and adenine base editors to alter the effector binding element(EBE)of TalC in the promoter of SWEET14 in rice cultivars Kitaake,IR24,and Zhonghua 11.Mutations with C to T changes in EBE led to reduced SWEET14 induction by TalC-containing Xoo strains,resulting in resistance to African Xoo isolates reliant on TalC for virulence.Conversely,A to G changes retained SWEET14 inducibility and susceptibility to Xoo in edited lines.Importantly,no off-target mutations were detected at predicted sites,and the edited lines exhibited no obvious defects in major agronomic traits in Kitaake.These results underscore the effectiveness of base editing systems for both molecular biology research and crop improvement endeavors.展开更多
Adenosine triphosphate(ATP)-binding cassette(ABC)transporter systems are divided into importers and exporters that facilitate the movement of diverse substrate molecules across the lipid bilayer,against the concentrat...Adenosine triphosphate(ATP)-binding cassette(ABC)transporter systems are divided into importers and exporters that facilitate the movement of diverse substrate molecules across the lipid bilayer,against the concentration gradient.These transporters comprise two highly conserved nucleotide-binding domains(NBDs)and two transmembrane domains(TMDs).Unlike ABC exporters,prokaryotic ABC importers require an additional substrate-binding protein(SBP)as a recognition site for specific substrate translocation.The discovery of a large number of ABC systems in bacterial pathogens revealed that these transporters are crucial for the establishment of bacterial infections.The existing literature has highlighted the roles of ABC transporters in bacterial growth,pathogenesis,and virulence.These roles include importing essential nutrients required for a variety of cellular processes and exporting outer membrane-associated virulence factors and antimicrobial substances.This review outlines the general structures and classification of ABC systems to provide a comprehensive view of the activities and roles of ABC transporters associated with bacterial virulence and pathogenesis during infection.展开更多
BACKGROUND Antibiotic resistance is a growing global health threat,and understanding local trends in bacterial isolates and their susceptibility patterns is crucial for effective infection control and antimicrobial st...BACKGROUND Antibiotic resistance is a growing global health threat,and understanding local trends in bacterial isolates and their susceptibility patterns is crucial for effective infection control and antimicrobial stewardship.The coronavirus disease 2019(COVID-19)pandemic has introduced additional complexities,potentially influencing these patterns.AIM To analyze trends in bacterial isolates and their antibiotic susceptibility patterns at Salmaniya Medical Complex from 2018 to 2023,with a specific focus on the impact of the COVID-19 pandemic on these trends.METHODS A retrospective analysis of microbiological data was conducted,covering the period from 2018 to 2023.The study included key bacterial pathogens such as Escherichia coli(E.coli),Klebsiella pneumoniae,Acinetobacter baumannii,Pseudomonas aeruginosa,and Staphylococcus aureus,among others.The antibiotic susceptibility profiles of these isolates were assessed using standard laboratory methods.To contextualize the findings,the findings were compared with similar studies from other regions,including China,India,Romania,Saudi Arabia,the United Arab Emirates,Malaysia,and United States.RESULTS The study revealed fluctuating trends in the prevalence of bacterial isolates,with notable changes during the COVID-19 pandemic.For example,a significant increase in the prevalence of Staphylococcus aureus was observed during the pandemic years,while the prevalence of E.coli showed a more variable pattern.Antibiotic resistance rates varied among the different pathogens,with a concerning rise in resistance to commonly used antibiotics,particularly among Klebsiella pneumoniae and E.coli.Additionally,the study identified an alarming increase in the prevalence of multidrug-resistant(MDR)strains,especially within Klebsiella pneumoniae and E.coli isolates.The impact of the COVID-19 pandemic on these trends was evident,with shifts in the frequency,resistance patterns,and the emergence of MDR bacteria among several key pathogens.CONCLUSION This study highlights the dynamic nature of bacterial isolates and their antibiotic susceptibility patterns at Salmaniya Medical Complex,particularly in the context of the COVID-19 pandemic.The findings underscore the need for continuous monitoring and effective anti-microbial stewardship programs to combat the evolving threat of antibiotic resistance.Further research and policy initiatives are required to address the identified challenges and improve patient outcomes in the face of these ongoing challenges.展开更多
The mini-review explores the potential use of alginates produced biotechnologically by bacteria for the development of various implantable biomaterials intended for bone and cartilage tissue regeneration in orthopedic...The mini-review explores the potential use of alginates produced biotechnologically by bacteria for the development of various implantable biomaterials intended for bone and cartilage tissue regeneration in orthopedics:the recent studies on the use of algal alginate-based biomaterials in the form of hydrogels,scaffolds,and microparticles for medical applications are considered as a potential opportunity to use bacterial alginate for these applications,taking into account the advantages of biotechnological production of a polymer with desired properties.The methods of producing different alginate-based biomaterials,the manufacturing of implantable medical devices using them,and the surgical techniques for bone and cartilage tissue regeneration using these materials for orthopedic purposes are discussed.展开更多
Spontaneous bacterial peritonitis(SBP)is a common complication of liver failure.It is an acute bacterial infection of the ascitic fluid in patients with liver cirrhosis.SBP presents a significant challenge for hepatol...Spontaneous bacterial peritonitis(SBP)is a common complication of liver failure.It is an acute bacterial infection of the ascitic fluid in patients with liver cirrhosis.SBP presents a significant challenge for hepatologists owing to its associated complications.While diagnostic paracentesis with polymorphonuclear count is highly accurate,it can be troublesome for some patients as it is an invasive procedure with associated risks.Several studies have proposed new diagnostic methods to improve current practices,many of which remain invasive.Although some serum tests show promise in the diagnosis of SBP,the results are still preliminary.Recent advancements in artificial intelligence and machine learning have introduced predictive models and scoring systems for diagnosis.However,these models still lack sufficient sensitivity,specificity,and the ability to effe-ctively assess treatment response.展开更多
Peanut(Arachis hypogaea L.)bacterial wilt(BW)is a devastating soil-borne disease caused by Ralstonia solanacearum(RS)that poses a significant threat to peanut yield and quality.Nucleotide-binding leucine-rich repeat(N...Peanut(Arachis hypogaea L.)bacterial wilt(BW)is a devastating soil-borne disease caused by Ralstonia solanacearum(RS)that poses a significant threat to peanut yield and quality.Nucleotide-binding leucine-rich repeat(NBS-LRR)proteins are a class of plant-specific immune receptors that recognize pathogen-secreted effector molecules and activate immune responses to resist pathogen infections.However,the precise functions of AhCN genes(where CN is a class of nucleotide-binding site,leucine-rich repeat receptor(NLR)genes that lack LRR structural domains)in peanut plants are not fully understood.In this study,a total of 150 AhCN genes were identified and classified into nine subfamilies based on a systematic phylogenetic analysis.The AhCN genes showed highly conserved structural features,and the promoter cis-elements indicated involvement in plant hormone signaling and defense responses.After inoculation with RS,the highly resistant peanut variety‘H108’significantly outperformed the susceptible variety‘H107’based on physiological indicators such as plant height,main stem diameter,and fresh weight,likely due to the inhibition of bacterial proliferation and diffusion in the stem vascular bundle.AhCN34 was found to be significantly upregulated in‘H108’compared to‘H107’during plant infection and in response to treatments with each of three plant hormones.Importantly,AhCN34 overexpression in peanut leaves enhanced their resistance to BW.These findings demonstrate the great potential of AhCN34 for applications in peanut resistance breeding.Our identification and characterization of the AhCN genes provide insights into the mechanisms underlying BW resistance in peanut and can inform future research into genetic methods of improving BW resistance in peanut.展开更多
The functional traits of soil fauna are closely related to ecosystem functions.The gut microbiota,which can reflect environmental changes,may be associated with functional traits.Therefore,in this study,collembolan(En...The functional traits of soil fauna are closely related to ecosystem functions.The gut microbiota,which can reflect environmental changes,may be associated with functional traits.Therefore,in this study,collembolan(Entomobrya proxima)was used to clarify the linkage response of specific gut taxa and traits under long-term urea exposure.A small amount of urea had positive effects on functional traits of E.proxima.Chao1 and Shannon indices of gut bacteria conditionally rare or abundant taxa(CRAT)gradually decreased under low and medium fertilizer,while increased under high fertilizer.Shannon index of abundant taxa(AT)showed a similar trend to that of CRAT except that the value of Shannon index was higher at high fertilizer than that of medium treatments.The structure and community assembly of CRAT changed significantly,and with the increase of urea addition amount,the dominant mechanism of community assembly changed from a deterministic process to a stochastic process.The niche width of AT and CRAT decreased.Relative abundance of some genera in AT and CRAT was closely related to functional traits.In conclusion,CRAT was more sensitive to urea than AT,had the potential to characterize functional traits of E.proxima,which will provide a basis for predicting the changes of soil animal traits and functions under the change of agricultural fertilizer strategy in the future.展开更多
Background:Bacterial pneumonia continues to be a significant global health concern,particularly among high-risk groups,necessitating the development of precise and early diagnostic biomarkers.While the efficacy of pro...Background:Bacterial pneumonia continues to be a significant global health concern,particularly among high-risk groups,necessitating the development of precise and early diagnostic biomarkers.While the efficacy of procalcitonin(PCT)and C-reactive protein(CRP)as inflammatory markers is widely recognized,their relative diagnostic performance across different age groups remains debate.This meta-analysis was designed to assess the diagnostic accuracy of PCT and CRP in bacterial pneumonia.Methods:In this meta-analysis adhering to PRISMA guidelines,we searched PubMed,Web of Science,and the Cochrane Library for relevant diagnostic accuracy studies.From 19 included studies(n=2,603),data were extracted to construct tables.Study quality was assessed with the QUADAS-2 tool.The bivariate random-effects model was employed to derive pooled sensitivity,specificity,positive and negative likelihood ratios,and summary AUCs.To explore the substantial heterogeneity(I^(2)>80%),we performed pre-specified subgroup analyses based on age demographics.Results:Our findings indicate superior diagnostic performance for PCT,evidenced by a pooled sensitivity of 0.8841 and specificity of 0.8499,relative to CRP’s sensitivity of 0.8371 and specificity of 0.7185.The area under the ROC curve(AUC)for PCT was 0.992,a value significantly higher than that of CRP(0.987).Intriguingly,subgroup analyses revealed age-dependent variations:CRP demonstrated enhanced diagnostic utility in minors,while PCT proved substantially more effective in non-elderly adults.Conclusion:These results reinforce the clinical relevance of PCT as a more dependable biomarker for bacterial pneumonia,particularly in informing antibiotic treatment and mitigating misuse.This study uniquely includes age-stratified analyses based on predefined groups(minors and non-elderly adults),providing refined insights for individualized diagnostic approaches.We propose further multicenter research endeavors to confirm threshold optimization and explore combined biomarker strategies.展开更多
Increasing attention has been paid to radioactive wastewater to direct discharge in Japan or accidental leaks.Strontium-90(90Sr)and Cobalt-60(^(60)Co)are the most hazardous nuclides in waste discharged form nuclear re...Increasing attention has been paid to radioactive wastewater to direct discharge in Japan or accidental leaks.Strontium-90(90Sr)and Cobalt-60(^(60)Co)are the most hazardous nuclides in waste discharged form nuclear reactors.Because of their high solubility and long half-lives,these radioisotopes can persist for hundreds of years before decaying to negligible levels.Herein,a green and biodegradable material nanoscale zero-valent iron(nZVI)supported by bacterial cellulose particles(BCP-nZVI)is constructed for the first time to adsorb Co^(2+)and Sr^(2+)in single and binary systems.BCP-nZVI shows superior adsorption capacities of Co^(2+)and Sr^(2+)in a single system within a wide range of pH values from 5 to 7,while the coexistence of Co^(2+)adsorption inhibits the Sr^(2+)in binary system.Pseudo-second-order dynamics model and Langmuir isothermal model can be indicated the BCP-nZVI adsorption progress with 107.10 mg/g(Co^(2+))and 64.96 mg/g(Sr^(2+))maximum adsorption capacity.BCP-nZVI has outstanding stability,allowing it to be stored for more than one month with compromising its performance.More importantly,BCP-nZVI exhibits exceptional removal efficiency of Co^(2+)(92.53%)and Sr^(2+)(58.62%)removal in natural seawater systems.The mechanism investigation illustrates the high adsorption capacity of BCP-nZVI for Co^(2+)is controlled by redox and hydroxyl complexation.While Sr^(2+)is controlled by hydroxyl complexed adsorption,thus it has weak against interference by cations like Na^(+),Ca^(2+),etc.BCP-nZVI exhibits the advantages of high adsorption capacity,wide pH range,strong stability,and good applicability in natural seawater,which has excellent potential for application in radioactive ions removal.展开更多
Transcription and translation are fundamental processes of gene expression across all three domains of life.These processes are evolutionarily ancient,with ribosomes already present in the last universal common ancest...Transcription and translation are fundamental processes of gene expression across all three domains of life.These processes are evolutionarily ancient,with ribosomes already present in the last universal common ancestor(LUCA)[1].While archaeal RNA polymerase(RNAP)and ribosomes exhibit more remarkable structural and functional similarity to their eukaryotic counterparts than to those of bacteria,the regulatory mechanisms governing transcription and translation in archaea closely resemble those found in bacteria[2].展开更多
Background:The bacterial biofilm poses a significant challenge to traditional antibiotic therapy.There is a great need to develop novel antibiofilm agents combined with biofilm disrupting and bacteria-killing without ...Background:The bacterial biofilm poses a significant challenge to traditional antibiotic therapy.There is a great need to develop novel antibiofilm agents combined with biofilm disrupting and bacteria-killing without the dependence of antibiotic.Methods:Herein,we prepared ultrasound/magnetic field-responsive ferroferric oxide nanoparticles(Fe_(3)O_(4))/glucose oxidase microbubbles(FGMB)to form a cascade catalytic system for effective removing methicillin-resistant Staphylococcus aureus biofilms.FGMB were prepared through interfacial self-assembly of Fe_(3)O_(4) nanoparticles(NPs)and glucose oxidase(GOx)at the gas-liquid interface stabilized by surfactants.Under ultrasound/magnetic field stimulation,FGMB disrupted biofilm architecture through microbubble collapse-induced microjets and magnetically driven displacement.Simultaneously,ultrasound-triggered rupture of FGMB released GOx and Fe_(3)O_(4) NPs.Glucose can be oxidized by GOx to generate gluconic acid and hydrogen peroxide which was subsequently catalyzed into hydroxyl radicals by Fe_(3)O_(4) NPs,enabling chemical eradication of biofilm-embedded bacteria.Results:Optical microscopy images demonstrated that FGMB have spherical structure with average size of approximately 17μm.FGMB showed a 65.4%decrease in methicillin-resistant Staphylococcus aureus biofilm biomass and 1.1 log bacterial inactivation efficiency(91.2%),suggesting effective biofilm elimination.In vitro experimental results also indicate that FGMB have good biocompatibility.Conclusion:This antibiofilm strategy integrated dual modes of physical biofilm disruption with chemical bacteria-killing shows great potential as a versatile,non-resistant strategy for bacterial biofilm elimination.展开更多
基金supported by the National Natural Science Foundation of China(Nos.32371734,42007034,41920104008,and U22A20593)the Strategic Priority Research Program of Chinese Academy of Sciences(No.XDA28020400)+2 种基金the Youth Innovation Promotion Association of Chinese Academy of Sciences(No.2023205)the Young Scientist Group Project of Northeast Institute of Geography and Agroecology of China(No.2022QNXZ04)the Science and Technology Development Project of Jilin Province of China(No.YDZJ202101ZYTS006).
文摘The conversion of saline-alkali soils into paddy fields for long-term rice cultivation involves multiple disturbances,and as a result,soil microbial communities are altered to adapt to changing environmental conditions.However,a comprehensive understanding of the succession of soil bacterial communities that occurs during this process is still lacking.In the present study,we utilized data obtained from paddy fields of different rice cultivation years(0-23 years)to investigate the compositional and functional succession of soil bacterial communities.We focused on core bacterial taxa that were specifically enriched at different successional stages.Generalized joint attribute modeling(GJAM)was used to identify core bacterial taxa.Results indicated that the bare saline-alkali soil(0 year,prior to any rice cultivation)shared few core amplicon sequence variants(ASVs)with paddy fields.In the bare saline-alkali soil,Longimicrobiaceae from the phylum Gemmatimonadetes was dominant,while the dominance was subsequently replaced by Burkholderiaceae and Pedosphaeraceae--phyla affiliated with Proteobacteria and Verrucomicrobia--after 5 and 23 years of rice cultivation,respectively.The relative abundances of nitrogen metabolism functions in the core bacterial communities of the bare saline-alkali soil were higher than those at other successional stages,while sulfur metabolism functions exhibited the opposite trend.These indicated that the role of the core bacterial taxa in mediating nutrient cycling also evolved and adapted to changing soil conditions as rice cultivation was established.Redundancy analysis(RDA)indicated that the composition of the core bacterial community in paddy fields with rice cultivation for 0,2 and 4,6,8,10,and 12,and 20 and 23 years were driven by soil nitrate nitrogen content,pH,available phosphorus content,and the ratio of total carbon to total nitrogen,respectively.In summary,the present study provides insights into the succession of soil bacterial communities and core bacterial taxa that occurs during long-term rice cultivation.
基金financially supported by the National Natural Science Foundation of China(No.32172855)Fundamental Research Funds for the Central Universities(Nos.2632024ZD07,2632024TD02)the Open Project of Jiangsu Provincial Science and Technology Resources(Clinical Resources)Coordination Service Platform(No.TC2023B001)。
文摘The presence of the blood–brain barrier limits the drug concentration in the brain,while low concentrations of antibiotics make it difficult to kill infecting bacteria and tends to induce drug resistance,making the clinical treatment of bacterial meningitis challenging.Herein,a nose-to-brain delivery strategy of small-sized nanozyme has been fabricated for combating bacterial meningitis,to overcome the low drug concentration and drug resistance.This strategy was achieved by a proteinsupported Au nanozyme(ANZ).With a particle size of less than 10 nm,it possesses both glucose oxidase-like and peroxidase-like activities and can generate large amounts of reactive oxygen species through a cascade effect without the addition of external H_(2)O_(2).Benefiting from the cascade catalytic amplification effect generated by its dual enzymelike activities,ANZ shows significant broad-spectrum antibacterial activity without inducing bacterial resistance in vitro.Notably,small-sized ANZ exhibits higher brain entry efficiency and greater accumulation after intranasal administration compared to oral or intravenous administration.In a mouse model of bacterial meningitis,the mice treated with ANZ had lower bacterial loads in the brain and higher survival and clinical behavior scores compared to the classical antibiotic ceftriaxone.Additionally,the meningitis mice exhibited undamaged cognitive and behavioral abilities,indicating the excellent biocompatibility of ANZ.The above results demonstrate that nose-to-brain delivery of ANZ exhibits high intracerebral accumulation,strong antibacterial efficacy and does not lead to bacterial resistance.It holds broad prospects for the treatment of bacterial meningitis.
文摘This study evaluated the antibacterial effects of 2%lidocaine and its combination with 0.9%saline solution on Escherichia coli infection in superficial surgical wounds in Wistar rats.The goal was to determine if these treatments could effectively reduce E.coli Colony Forming Units(CFUs)below the critical threshold of 1×105.Seventy male Wistar rats were divided into seven groups,each undergoing different interventions to assess the antibacterial efficacy of lidocaine,with outcomes measured through bacterial cultures and CFU quantification.Results demonstrated a Log10reduction of approximately 0.44 in E.coli CFUs following infiltration with 2%lidocaine.The combined use of 2%lidocaine infiltration and 0.9%saline irrigation resulted in nearly complete suppression of bacterial growth.These findings suggest that these simple interventions could be valuable in emergency surgical settings to mitigate the risk of surgical site infections and serve as effective prophylactic measures.increase in hospital stay,which represents an additional cost in terms of expenses and directly impacts the patient's outcome.11Several lines of evidence point to 104colony forming units per gram of tissue(CFUs/g)as the threshold at which healing generally begins to slow.12Knowledge of the antibacterial activity of lidocaine has been used to prevent bacterial contamination of other lipid-based anesthetics,such as propofol,with a significant decrease in bacterial development13-15and its antifungal effect.15,16Other effects attributed to lidocaine concerning systemic inflammatory response are the inhibition of granulocyte adhesion at sites of inflammation,decreased leukocyte adhesion during endotoxemia,and decreased macromolecular filtration;it is suggested that it may play a therapeutic role in endothelial damage during sepsis.17-19On the other hand,different measures have been taken to reduce the surgical wound infection rate,such as prophylactic antibiotics and local wound care,including pressure irrigation with 0.9% saline solution,with good results.20The antibacterial effect of lidocaine has been demonstrated in an animal model21;however,no model resembles surgical wound infection and the use of lidocaine to prevent infection.This study aimed to demonstrate that using 2% lidocaine(2 mL/g of tissue)will reduce the E.coli CFUs below 1×105in an infected superficial surgical wound in an experimental model.
基金financially supported by the National Key Research and Development Program of China(Nos.2022YFC2406000 and 2021YFC2400402)the National Natural Science Foundation of China(Nos.52101285,51932002,U21A2055 and U22A20160)
文摘Bacterial infection presents formidable challenges that frequently culminate in the malfunction of metal implants.Traditional surface treatment methods struggle to effectively achieve controllable management of bacterial infections associated with metal implants.To effectively enhance the antibacterial capabilities and preventing bacterial adhesion,electroactive materials have emerged as a groundbreaking strategy for surface modification of metal.By responding to external signals,the electroactive materials can improve antibacterial properties and resistance to bacterial adhesion on the implant surface through harnessing the electrostatic interaction of charges,ion release,oxidation of reactive oxygen species(ROS),electron transfer,and the involvement of cellular immunity.This review delves into the principles of how electroactive materials confer implants with antibacterial properties and antibacterial adhesion,while also summarizing the latest research breakthroughs in their application for surface modification.These strategies successfully strike a balance between the antibacterial and the antimicrobial performance of the implant surface.Lastly,the review examines the limitations and ongoing challenges faced by electroactive material modification technology in implant applications,and sketches out the future trajectory and potential innovative avenues in this promising field.
基金supported by NSF 2333230 (J.L.),NIH National Institute of Dental and Craniofacial Research (NIDCR) awards,DE030943 (X.H.),DE023810 (X.H.) and DE031329 (J.L.),T90 DE026110,and K99 DE033794 (to P.-T.D.)
文摘Host-derived small RNAs are emerging as critical regulators in the dynamic interactions between host tissues and the microbiome,with implications for microbial pathogenesis and host defense.Among these,transfer RNA-derived small RNAs(tsRNAs)have garnered attention for their roles in modulating microbial behavior.However,the bacterial factors mediating tsRNA interaction and functionality remain poorly understood.In this study,using RNA affinity pull-down assay in combination with mass spectrometry,we identified a putative membrane-bound protein,annotated as P-type ATPase transporter(PtaT)in Fusobacterium nucleatum(Fn),which binds Fn-targeting tsRNAs in a sequence-specific manner.Through targeted mutagenesis and phenotypic characterization,we showed that in both the Fn type strain and a clinical tumor isolate,deletion of ptaT led to reduced tsRNA intake and enhanced resistance to tsRNA-induced growth inhibition.Global RNA sequencing and label-free Raman spectroscopy revealed the phenotypic differences between Fn wild type and PtaT-deficient mutant,highlighting the functional significance of PtaT in purine and pyrimidine metabolism.Furthermore,AlphaFold 3 prediction provides evidence supporting the specific binding between PtaT and Fn-targeting tsRNA.By uncovering the first RNA-binding protein in Fn implicated in growth modulation through interactions with host-derived small RNAs(sRNAs),our study offers new insights into sRNA-mediated host-pathogen interplay within the context of microbiome-host interactions.
文摘Honey, an apicultural product with a complex chemical composition, contains numerous bioactive compounds with potential antimicrobial effects. This study investigated the effect of Apis mellifera honey from Brazil’s Central-West Region, combined with antibiotics, on bacterial membrane permeability, exploring the contributions of bioactive compounds and the botanical origin of honey. Six fresh Apis mellifera honey samples and their fractions (hexane and ethyl acetate) were analyzed, for a total of 18 samples. The bacteria Staphylococcus epidermidis, Helicobacter pylori and Enterococcus faecalis were used for antibacterial activity tests, which included minimum inhibitory concentration (MIC) determination and synergistic effect (checkerboard) assays. The total polyphenol and flavonoid contents were quantified, and the botanical origin was determined based on pollen analysis. The tested honey samples significantly affected bacterial membrane permeability when combined with rifampicin and clarithromycin. Although many honey-derived bioactive compounds, when isolated, did not exhibit significant activity against these bacteria, the additive or synergistic effect of multiple compounds acting on different targets appears to potentiate the antibacterial action. Descriptive statistical analysis, including means and 95% confidence intervals, confirmed the relevance of the findings. This study has provided an important discovery: Honey has an effect on bacterial membrane permeability, although the specific mechanisms involved in this process require further investigation.
基金supported by National Natural Science Foundation of China(32272153)Henan Province Science and Technology R&D Joint Fund(232301420025)+4 种基金National Key Research and Development Program of China(2023YFD1200200)the Key Research Project of the Shennong Laboratory(SN01-2022-03)Independent Innovation Foundation of Henan Academy of Agricultural Sciences(2024ZC024)China Agriculture Research System(CARS-13)Henan Provincial Agriculture Research System(S2012-5).
文摘Wild peanut(Arachis)species are promising sources of disease resistance for improving peanut cultivars.The objective of this study was to assess cross-compatibility among cultivated and wild peanuts in crosses between eight peanut cultivars and 27 wild species carrying the A,B,E,Ex,F,K,P,and H genomes.Embryo culture and chromosome doubling led to polyploids representing hybrids between cultivated peanut and A.stenosperma,A.macedoi,A.duranensis,A.villosa,and A.diogoi.The first two showed greater resistance to bacterial wilt than their cultivated parents.DNA markers were developed for verifying the hybrids and for identifying translocation or introgression lines with alien chromosome fragments.
基金supported by the Key-Area Research and Development Program of Guangdong Province,China(No.2021B0202030002)the Science and Technology Planning Project of Guangdong Province,China(No.2019B030301007)+2 种基金the Guangdong Provincial Special Project of Rural Revitalization Strategy,China(No.(2021)12)the Joint Team Project of Guangdong Laboratory for Lingnan Modern Agriculture,China(No.NT2021010)the Innovation Team Construction Project of Modern Agricultural Industry Technology Systems of Guangdong Province,China(No.2022KJ105).
文摘Rice-fish coculture(RFC)has aroused extensive concern for its contribution to food security and resource conservation,but whether it can improve soil phosphorus(P)availability and affect microbe-mediated P turnover remains elusive.Herein,we conducted a microcosm experiment to assess the impacts of RFC combined with(50 mg P kg^(-1)as KH2PO4)and without inorganic P addition on P fractions,P availability,and phoD-harboring bacterial community composition.The results revealed that RFC without P addition significantly improved P availability and phosphatase activity in paddy soil,while soil available P(AP),pH,and microbial biomass P(MBP)contributed to regulating P fractions.Moreover,the phoD-harboring bacterial abundance was linked to phosphatase activity,AP,total carbon(TC),and total P(TP)contents,and the ratios of TC to total nitrogen(TN)and TN to TP.We also found that the keystone taxa of phoD-harboring bacteria contributed to phosphatase production as well as organic P mineralization,thereby improving P availability.Our findings suggest that RFC without P addition is beneficial for promoting the expression of phoD-harboring bacterial functions to improve the capacity of P mineralization.Overall,our study provides insights into the responses of phoD-harboring bacterial functions for P turnover to RFC combined with and without P addition,showing the potential utilization of P resources in agricultural soil and the contribution of phosphatase activity to P acquisition in agriculture ecosystem.
文摘Solar-driven Fenton-like reactions are promising strategies for degrading pharmaceutical wastewater to address environmental challenges and antibiotic pollution.However,its efficacy is limited by suboptimal light absorption efficiency,rapid charge recombination,and inadequate interfacial charge transfer.In this study,an inorganic/organic S-scheme photo-Fenton system of pseudobrookite/carbon nitride(FTOCN)was synthesized via a hydrothermally coupled calcination process for the effective purification of tetracycline antibiotics under visible-light irradiation.The optimized FTOCN-2 heterostructure exhibits a significantly enhanced TC degradation capacity of 90%within 60 min.The rate constant of FTOCN-2 is 1.6 and 5.2 times greater than those of FTO and CN,respectively.Furthermore,FTOCN exhibits high antibacterial efficacy,highlighting its potential application in the purification of natural water.Measurements via a range of analytical techniques,including Kelvin probe force microscopy,density functional theory calculations,in situ X-ray photoelectron spectroscopy,and femtosecond transient absorption spectroscopy,corroborate the S-scheme mechanism.This study provides a novel perspective for the development of photo-Fenton systems with S-scheme heterojunctions for water purification.
基金supported by a sub-award to the University of Missouri from the Heinrich Heine University of Dusseldorf funded by the Bill&Melinda Gates Foundation(OPP1155704)(Bing Yang)and the China Scholar Council(Chenhao Li,as a joint Ph.D.student).
文摘Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is crucial to advancing rice breeding program and supporting smallholder farmers.Transcription Activator-Like effectors(TALes)are key virulence factors in Xoo,with some targeting the susceptibility(S)genes such as the sugar transporter SWEET genes in rice.Among these,SWEET14 is an important S gene,with its promoter bound by the TALe TalC which exists across all sequenced African Xoo isolates.In the present study,we utilized CRISPR/Cas9-based cytidine and adenine base editors to alter the effector binding element(EBE)of TalC in the promoter of SWEET14 in rice cultivars Kitaake,IR24,and Zhonghua 11.Mutations with C to T changes in EBE led to reduced SWEET14 induction by TalC-containing Xoo strains,resulting in resistance to African Xoo isolates reliant on TalC for virulence.Conversely,A to G changes retained SWEET14 inducibility and susceptibility to Xoo in edited lines.Importantly,no off-target mutations were detected at predicted sites,and the edited lines exhibited no obvious defects in major agronomic traits in Kitaake.These results underscore the effectiveness of base editing systems for both molecular biology research and crop improvement endeavors.
基金supported by the Universiti Kebangsaan Malaysia under the Research University Grant(No.GUP-2020-030)awarded to Sylvia CHIENG.
文摘Adenosine triphosphate(ATP)-binding cassette(ABC)transporter systems are divided into importers and exporters that facilitate the movement of diverse substrate molecules across the lipid bilayer,against the concentration gradient.These transporters comprise two highly conserved nucleotide-binding domains(NBDs)and two transmembrane domains(TMDs).Unlike ABC exporters,prokaryotic ABC importers require an additional substrate-binding protein(SBP)as a recognition site for specific substrate translocation.The discovery of a large number of ABC systems in bacterial pathogens revealed that these transporters are crucial for the establishment of bacterial infections.The existing literature has highlighted the roles of ABC transporters in bacterial growth,pathogenesis,and virulence.These roles include importing essential nutrients required for a variety of cellular processes and exporting outer membrane-associated virulence factors and antimicrobial substances.This review outlines the general structures and classification of ABC systems to provide a comprehensive view of the activities and roles of ABC transporters associated with bacterial virulence and pathogenesis during infection.
文摘BACKGROUND Antibiotic resistance is a growing global health threat,and understanding local trends in bacterial isolates and their susceptibility patterns is crucial for effective infection control and antimicrobial stewardship.The coronavirus disease 2019(COVID-19)pandemic has introduced additional complexities,potentially influencing these patterns.AIM To analyze trends in bacterial isolates and their antibiotic susceptibility patterns at Salmaniya Medical Complex from 2018 to 2023,with a specific focus on the impact of the COVID-19 pandemic on these trends.METHODS A retrospective analysis of microbiological data was conducted,covering the period from 2018 to 2023.The study included key bacterial pathogens such as Escherichia coli(E.coli),Klebsiella pneumoniae,Acinetobacter baumannii,Pseudomonas aeruginosa,and Staphylococcus aureus,among others.The antibiotic susceptibility profiles of these isolates were assessed using standard laboratory methods.To contextualize the findings,the findings were compared with similar studies from other regions,including China,India,Romania,Saudi Arabia,the United Arab Emirates,Malaysia,and United States.RESULTS The study revealed fluctuating trends in the prevalence of bacterial isolates,with notable changes during the COVID-19 pandemic.For example,a significant increase in the prevalence of Staphylococcus aureus was observed during the pandemic years,while the prevalence of E.coli showed a more variable pattern.Antibiotic resistance rates varied among the different pathogens,with a concerning rise in resistance to commonly used antibiotics,particularly among Klebsiella pneumoniae and E.coli.Additionally,the study identified an alarming increase in the prevalence of multidrug-resistant(MDR)strains,especially within Klebsiella pneumoniae and E.coli isolates.The impact of the COVID-19 pandemic on these trends was evident,with shifts in the frequency,resistance patterns,and the emergence of MDR bacteria among several key pathogens.CONCLUSION This study highlights the dynamic nature of bacterial isolates and their antibiotic susceptibility patterns at Salmaniya Medical Complex,particularly in the context of the COVID-19 pandemic.The findings underscore the need for continuous monitoring and effective anti-microbial stewardship programs to combat the evolving threat of antibiotic resistance.Further research and policy initiatives are required to address the identified challenges and improve patient outcomes in the face of these ongoing challenges.
基金Supported by Russian Science Foundation,No.23-74-10027.
文摘The mini-review explores the potential use of alginates produced biotechnologically by bacteria for the development of various implantable biomaterials intended for bone and cartilage tissue regeneration in orthopedics:the recent studies on the use of algal alginate-based biomaterials in the form of hydrogels,scaffolds,and microparticles for medical applications are considered as a potential opportunity to use bacterial alginate for these applications,taking into account the advantages of biotechnological production of a polymer with desired properties.The methods of producing different alginate-based biomaterials,the manufacturing of implantable medical devices using them,and the surgical techniques for bone and cartilage tissue regeneration using these materials for orthopedic purposes are discussed.
文摘Spontaneous bacterial peritonitis(SBP)is a common complication of liver failure.It is an acute bacterial infection of the ascitic fluid in patients with liver cirrhosis.SBP presents a significant challenge for hepatologists owing to its associated complications.While diagnostic paracentesis with polymorphonuclear count is highly accurate,it can be troublesome for some patients as it is an invasive procedure with associated risks.Several studies have proposed new diagnostic methods to improve current practices,many of which remain invasive.Although some serum tests show promise in the diagnosis of SBP,the results are still preliminary.Recent advancements in artificial intelligence and machine learning have introduced predictive models and scoring systems for diagnosis.However,these models still lack sufficient sensitivity,specificity,and the ability to effe-ctively assess treatment response.
基金supported by the grants from the National Natural Science Foundation of China(NSFC)-Henan United Fund(U22A20475 and U1704232)the Key Scientific and Technological Project of Henan Province,China(221111110500,161100111000,and HARS-22-05-G1)+2 种基金the Innovation Scientists and Technicians Troop Construction Projects of Henan Province,China(2018JR0001)the Henan Agricultural University High Level Talent Special Support Fund,China(30501418)the Key Scientific Research Project in Colleges and Universities of Henan Province,China(21A210018).
文摘Peanut(Arachis hypogaea L.)bacterial wilt(BW)is a devastating soil-borne disease caused by Ralstonia solanacearum(RS)that poses a significant threat to peanut yield and quality.Nucleotide-binding leucine-rich repeat(NBS-LRR)proteins are a class of plant-specific immune receptors that recognize pathogen-secreted effector molecules and activate immune responses to resist pathogen infections.However,the precise functions of AhCN genes(where CN is a class of nucleotide-binding site,leucine-rich repeat receptor(NLR)genes that lack LRR structural domains)in peanut plants are not fully understood.In this study,a total of 150 AhCN genes were identified and classified into nine subfamilies based on a systematic phylogenetic analysis.The AhCN genes showed highly conserved structural features,and the promoter cis-elements indicated involvement in plant hormone signaling and defense responses.After inoculation with RS,the highly resistant peanut variety‘H108’significantly outperformed the susceptible variety‘H107’based on physiological indicators such as plant height,main stem diameter,and fresh weight,likely due to the inhibition of bacterial proliferation and diffusion in the stem vascular bundle.AhCN34 was found to be significantly upregulated in‘H108’compared to‘H107’during plant infection and in response to treatments with each of three plant hormones.Importantly,AhCN34 overexpression in peanut leaves enhanced their resistance to BW.These findings demonstrate the great potential of AhCN34 for applications in peanut resistance breeding.Our identification and characterization of the AhCN genes provide insights into the mechanisms underlying BW resistance in peanut and can inform future research into genetic methods of improving BW resistance in peanut.
基金funded by the Scientific and Technological Innovation Project of the Chinese Academy of Agricultural Sciences(Grant No.CAASZDRW202408).
文摘The functional traits of soil fauna are closely related to ecosystem functions.The gut microbiota,which can reflect environmental changes,may be associated with functional traits.Therefore,in this study,collembolan(Entomobrya proxima)was used to clarify the linkage response of specific gut taxa and traits under long-term urea exposure.A small amount of urea had positive effects on functional traits of E.proxima.Chao1 and Shannon indices of gut bacteria conditionally rare or abundant taxa(CRAT)gradually decreased under low and medium fertilizer,while increased under high fertilizer.Shannon index of abundant taxa(AT)showed a similar trend to that of CRAT except that the value of Shannon index was higher at high fertilizer than that of medium treatments.The structure and community assembly of CRAT changed significantly,and with the increase of urea addition amount,the dominant mechanism of community assembly changed from a deterministic process to a stochastic process.The niche width of AT and CRAT decreased.Relative abundance of some genera in AT and CRAT was closely related to functional traits.In conclusion,CRAT was more sensitive to urea than AT,had the potential to characterize functional traits of E.proxima,which will provide a basis for predicting the changes of soil animal traits and functions under the change of agricultural fertilizer strategy in the future.
基金supported by the National Natural Science Foundation of China(82360801,82460822)Natural Science Foundation of Inner Mongolia Autonomous Region(2022LHQN08001,2023QN08050,2025LHMS08061)+4 种基金the Scientific Research Project of Higher Education Institutions in Inner Mongolia Autonomous Region(NJZY23135)the Laboratory Open Fund of Inner Mongolia Medical University(2024ZN23)and the General Project of Inner Mongolia Medical University(YKD2025MS047Inner Mongolia Medical University Undergraduate Science and Technology Innovation"Talent Cultivation"Project(YCPY2025028,YCPY2025024)Inner Mongolia Medical University Undergraduate Innovation and Entrepreneurship Training Program Project(101322025034).
文摘Background:Bacterial pneumonia continues to be a significant global health concern,particularly among high-risk groups,necessitating the development of precise and early diagnostic biomarkers.While the efficacy of procalcitonin(PCT)and C-reactive protein(CRP)as inflammatory markers is widely recognized,their relative diagnostic performance across different age groups remains debate.This meta-analysis was designed to assess the diagnostic accuracy of PCT and CRP in bacterial pneumonia.Methods:In this meta-analysis adhering to PRISMA guidelines,we searched PubMed,Web of Science,and the Cochrane Library for relevant diagnostic accuracy studies.From 19 included studies(n=2,603),data were extracted to construct tables.Study quality was assessed with the QUADAS-2 tool.The bivariate random-effects model was employed to derive pooled sensitivity,specificity,positive and negative likelihood ratios,and summary AUCs.To explore the substantial heterogeneity(I^(2)>80%),we performed pre-specified subgroup analyses based on age demographics.Results:Our findings indicate superior diagnostic performance for PCT,evidenced by a pooled sensitivity of 0.8841 and specificity of 0.8499,relative to CRP’s sensitivity of 0.8371 and specificity of 0.7185.The area under the ROC curve(AUC)for PCT was 0.992,a value significantly higher than that of CRP(0.987).Intriguingly,subgroup analyses revealed age-dependent variations:CRP demonstrated enhanced diagnostic utility in minors,while PCT proved substantially more effective in non-elderly adults.Conclusion:These results reinforce the clinical relevance of PCT as a more dependable biomarker for bacterial pneumonia,particularly in informing antibiotic treatment and mitigating misuse.This study uniquely includes age-stratified analyses based on predefined groups(minors and non-elderly adults),providing refined insights for individualized diagnostic approaches.We propose further multicenter research endeavors to confirm threshold optimization and explore combined biomarker strategies.
基金supported by the National Natural Science Foundation of China(Nos.51778618 and 52070192)the State Key Laboratory of Materials-Oriented Chemical Engineering(No.SKL-MCE-23B09)the open fund of Information Materials and Intelligent Sensing Laboratory of Anhui Province(No.IMIS202213).
文摘Increasing attention has been paid to radioactive wastewater to direct discharge in Japan or accidental leaks.Strontium-90(90Sr)and Cobalt-60(^(60)Co)are the most hazardous nuclides in waste discharged form nuclear reactors.Because of their high solubility and long half-lives,these radioisotopes can persist for hundreds of years before decaying to negligible levels.Herein,a green and biodegradable material nanoscale zero-valent iron(nZVI)supported by bacterial cellulose particles(BCP-nZVI)is constructed for the first time to adsorb Co^(2+)and Sr^(2+)in single and binary systems.BCP-nZVI shows superior adsorption capacities of Co^(2+)and Sr^(2+)in a single system within a wide range of pH values from 5 to 7,while the coexistence of Co^(2+)adsorption inhibits the Sr^(2+)in binary system.Pseudo-second-order dynamics model and Langmuir isothermal model can be indicated the BCP-nZVI adsorption progress with 107.10 mg/g(Co^(2+))and 64.96 mg/g(Sr^(2+))maximum adsorption capacity.BCP-nZVI has outstanding stability,allowing it to be stored for more than one month with compromising its performance.More importantly,BCP-nZVI exhibits exceptional removal efficiency of Co^(2+)(92.53%)and Sr^(2+)(58.62%)removal in natural seawater systems.The mechanism investigation illustrates the high adsorption capacity of BCP-nZVI for Co^(2+)is controlled by redox and hydroxyl complexation.While Sr^(2+)is controlled by hydroxyl complexed adsorption,thus it has weak against interference by cations like Na^(+),Ca^(2+),etc.BCP-nZVI exhibits the advantages of high adsorption capacity,wide pH range,strong stability,and good applicability in natural seawater,which has excellent potential for application in radioactive ions removal.
基金supported by the National Key Research and Development Program of China(grant number 2024YFC2309300 to C.W.)the Natural Science Foundation of China(grant number 32270039 to C.W.)+1 种基金Shanghai Science and Technology Innovation Action Plan 2023“Basic Research Project”(grant number 23JC1404201 to C.W.)the Russian Science Foundation grant(grant number RSF 25-74-30007 to V.M.).
文摘Transcription and translation are fundamental processes of gene expression across all three domains of life.These processes are evolutionarily ancient,with ribosomes already present in the last universal common ancestor(LUCA)[1].While archaeal RNA polymerase(RNAP)and ribosomes exhibit more remarkable structural and functional similarity to their eukaryotic counterparts than to those of bacteria,the regulatory mechanisms governing transcription and translation in archaea closely resemble those found in bacteria[2].
基金supported by the National Natural Science Foundation of China(22375101)the Natural Science of Colleges and Universities in Jiangsu Province(24KJB430027).
文摘Background:The bacterial biofilm poses a significant challenge to traditional antibiotic therapy.There is a great need to develop novel antibiofilm agents combined with biofilm disrupting and bacteria-killing without the dependence of antibiotic.Methods:Herein,we prepared ultrasound/magnetic field-responsive ferroferric oxide nanoparticles(Fe_(3)O_(4))/glucose oxidase microbubbles(FGMB)to form a cascade catalytic system for effective removing methicillin-resistant Staphylococcus aureus biofilms.FGMB were prepared through interfacial self-assembly of Fe_(3)O_(4) nanoparticles(NPs)and glucose oxidase(GOx)at the gas-liquid interface stabilized by surfactants.Under ultrasound/magnetic field stimulation,FGMB disrupted biofilm architecture through microbubble collapse-induced microjets and magnetically driven displacement.Simultaneously,ultrasound-triggered rupture of FGMB released GOx and Fe_(3)O_(4) NPs.Glucose can be oxidized by GOx to generate gluconic acid and hydrogen peroxide which was subsequently catalyzed into hydroxyl radicals by Fe_(3)O_(4) NPs,enabling chemical eradication of biofilm-embedded bacteria.Results:Optical microscopy images demonstrated that FGMB have spherical structure with average size of approximately 17μm.FGMB showed a 65.4%decrease in methicillin-resistant Staphylococcus aureus biofilm biomass and 1.1 log bacterial inactivation efficiency(91.2%),suggesting effective biofilm elimination.In vitro experimental results also indicate that FGMB have good biocompatibility.Conclusion:This antibiofilm strategy integrated dual modes of physical biofilm disruption with chemical bacteria-killing shows great potential as a versatile,non-resistant strategy for bacterial biofilm elimination.
